KR101349213B1 - System for verifying elevation by leveling survey - Google Patents

Abstract

A system for checking a true height through leveling can conduct leveling in dark circumstances and automatically clean the surface of a leveling rod by including a dust removing body which can clean the surface of the leveling rod at one side of the leveling rod and including a light emitting sheet on the back surface of the leveling rod for emitting light. In addition, the system for checking a true height has a horizontal regulating device that can regulate the leveling rod to be kept level by sensing the gradient of the leveling rod in order to correctly stand the leveling rod by regulating horizontality according to the ground condition, thereby ensuring an accurate gradation check. [Reference numerals] (12,430,530) Control unit; (13,522) GPS receiver; (14,520) GPS antenna; (15,510) DGPS antenna; (16) DGPS transmitter; (400) Distance measuring device; (410) Transmitter; (420) Driving unit; (440) Power unit; (512) DGPS receiver; (540) Input device; (610) Storage unit; (620) True height information transmitting module; (910) Receiving module; (920) True height information DB; (930) Display module

Description

System for Verifying Elevation by Leveling Survey}

The present invention relates to a system for checking the elevation through leveling, and more specifically, it is possible to automatically wipe the surface of the surface and to emit the surface, so that the level can be measured even in a dark environment. It is related to the elevation check system through level surveying, which allows the accurate positioning of scales.

In general, surveying takes place for various civil and architectural designs. Surveying refers to all activities that measure horizontal distance, elevation, and direction to determine the location of points, express them in drawings or figures, and stake out in the field.

Among these, level surveying is a survey that obtains the height difference between two points by using a top and staff.

This leveling is generally done as follows.

First, the surface level is set at the ground reference point where the elevation is known, and the mechanical number reads the scale of the surface with the level at the first observation point a certain distance away.

The surface water then moves to the first point to establish the surface, and the mechanical number reads the scale of the surface at the first point.

Here, the elevation of the first point is obtained from the difference of the scale read from the ground reference point and the first point and the elevation of the ground reference point.

Next, the mechanical number moves to the second observation point after the first point, and when the surface number reverses the surface in place so that the surface looks at the level, the mechanical number reads the scale of the surface.

The surface water then moves to the second point to establish the surface, and the mechanical number reads the scale of the surface at the second point.

Here, the elevation of the second point is obtained from the difference in scale between the first point and the second point read at the second observation point.

In this way, the level and leveler are continuously moved, and the direction of the level and leveler is changed at each point to read the scale to obtain the elevation of each point up to the target point.

In the conventional level measurement, the scale should be read in place by changing the direction of the scale, and various errors occur according to the state of the ground.

Conventional leveling has a problem that it is difficult for the number of machines to accurately check the scale of the scale when the work is performed in the dark or at night.

In addition, in the conventional level measurement, when foreign matter such as dust is buried on the surface of the surface and the scale is not accurately seen, the foreign matters on the surface must be removed because the mechanical number is difficult to check the scale of the surface.

If the surface water has foreign matter on the surface, it has to be difficult to clean the surface every time the surface has to be cleaned.

Republic of Korea Patent No. 10-1227189 (Registration date: January 22, 2013), the title of the invention: "Elevation information confirmation system through precision leveling"

In order to solve the problems and necessity of the prior art, the present invention can automatically clean the surface of the surface of the surface of the surface of the surface of the surface of the surface of the surface of the surface of the surface. Its purpose is to provide an elevation verification system through level surveying, which can be accurately set up to ensure accurate graduations.

Altitude confirmation system through the leveling of the present invention for achieving the above object,

An accommodation space 211 formed therein, a distance measuring device installation hole 212 disposed in a lower portion of the accommodation space 211 and communicating with the accommodation space 211 and opening downward, and the accommodation space 211 It is disposed in the upper portion to form a top surface insertion hole 213 in communication with the receiving space 211 is opened upwards, is detachably inserted into the top surface insertion hole 213 is built in a predetermined length in the vertical direction and the circumferential surface The scale 300 is displayed on the scale and the distance measuring device 400 is installed in the distance measuring device installation hole 212 of the surface mounting mechanism 200 and measures the distance from the bottom surface of the surface 300 to the ground and Is installed on the surface mounting mechanism 200, the body portion 210 including a transmitter 410 for transmitting the distance value of the distance measuring unit 400, and the horizontal adjustment device 700 in the lower portion of the body portion 210 ) To form a support portion 800 in the lower portion of the horizontal adjustment device 700 Installation chuck mechanism (200);

It is provided with an input device 540 for checking the scale of the scale 300 installed in the surface mounting mechanism 200 and input the checked scale, and the scale and distance measurer 400 from the input device 540 A leveler 500 for calculating the height from the ground to the scale of the scale 300 by calculating a distance value from the ground;

Elevation information collector 600 having a storage unit 610 for storing the elevation information of each point collected using the leveler 500, and the elevation information transmission module 620 for transmitting the elevation information. Elevation information collector 600; And

Receiving module 910 for receiving each of the elevation information obtained at a plurality of points from the elevation information transmitting module 620 of the elevation information collector 600, and the elevation information DB 920 for storing elevation information for each point. And an elevation information collection device 900 including a display module 930 for displaying elevation information stored in the elevation information DB 920,

The top surface 300 is made of a dust of a cloth material formed between the top surface support hole 302 is formed between the top surface support hole 302 and the top surface 300 and the top support 306 to form a pipe shape to surround the rim And a dust removing body 310 forming a rejection 308 and forming a gear connecting body 309 connected to the rack gear 320, wherein the rack gear 320 accommodates the body portion 210. It is formed in the space 211 and connected to the top 300 by using the dust removing body 310 on one side of the bottom 300, the rack gear 320 is the pinion gear in the receiving space (211) 330 is moved up and down in accordance with the rotation of the pinion gear 330, and corresponds to the length of the top 300, and integrally coupled with the dust removal body 310 to move up and down the rack gear 320 In accordance with the dust removal body 310 is also moved in the vertical direction of the surface 300 is the surface of the surface 300 And cleaning the foreign matter,

A light emitting sheet 350 is installed on the rear surface of the top surface 300 to emit light, and the horizontal adjusting device 700 moves downward from the first support plate 712 and the first support plate 712 in the form of a plate. An upper hinge portion 722 is formed on the lower side of the first support plate 712, and the second support plate including a body 710 consisting of a second support plate 714 spaced apart from a certain distance; The first support plate 712 is formed of a lower hinge portion 724 formed on the upper side of the 714, and a hinge pin 726 for rotatably coupling the upper hinge portion 722 and the lower hinge portion 724 to each other. Hinge means 720 to enable horizontal adjustment, the balance weight 734 is formed on the lower side of the first support plate 712 is installed to be rotated left and right according to the inclination of the first support plate 712, and The left and right proximity sensors 736 and 738 which are spaced apart at regular intervals on the left and right sides of the balance weight 734, Sensing means 730 for detecting the inclination of the first support plate 712 and the first support plate 712 according to the control signal received from the sensing means 730 is installed on the upper side of the second support plate 714 It includes a driving means 740 to maintain the horizontal by adjusting the angle of the).

The present invention having the configuration as described above is provided with a dust removing body on one side of the top surface and using the rack gear and pinion gear to move the dust removing body in the vertical direction of the top surface has the effect of automatically cleaning the surface of the top surface.

According to the present invention, the light emitting sheet is provided on the rear surface of the top surface to emit light, thereby enabling level measurement even in a dark environment.

The present invention is equipped with a horizontal adjustment device in the surface mounting mechanism can adjust the horizontal level according to the state on the ground, so that the exact height of the scale can be accurately checked the scale of the scale.

1 is a view showing the configuration of the elevation check system through the level measurement according to an embodiment of the present invention.
Figure 2 is a front view showing the configuration of the surface mounting mechanism according to an embodiment of the present invention.
Figure 3 is a perspective view showing the configuration of the surface mounting mechanism according to an embodiment of the present invention.
4 is a view showing a dust removing body and a rack gear of the surface mounting mechanism according to an embodiment of the present invention.
5 is a view showing the vertical movement of the dust removing body in accordance with the movement of the rack gear of the surface mounting mechanism according to an embodiment of the present invention.
6 is a view showing the top and the light emitting sheet of the top mounting mechanism according to an embodiment of the present invention.
7 is a view showing the configuration of the horizontal adjustment device of the top mounting mechanism according to an embodiment of the present invention.
8 is a view showing a top mounting mechanism and a leveler according to an embodiment of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise.

The level check system through the conventional level measurement system is difficult to check the scale of the scale if the scale is not visible because of the foreign matter such as dust on the surface of the surface. Therefore, it is difficult to check the scale of the scale. In case of failing to match, there was a problem that it was difficult to check the accurate scale due to an error of the scale of the scale.

The present invention is provided with a dust removal body that can wipe the surface of the surface on one side of the surface of the surface of the surface of the surface of the surface of the surface of the surface of the surface of the surface of the surface of the surface of the surface of the surface of the surface of the surface. The level is adjusted according to the condition of, and because of this, the level can be set accurately, thus providing the level checking system through the level measurement, which enables accurate check of the level of the level.

1 is a view showing the configuration of the elevation check system through a level measurement according to an embodiment of the present invention, Figure 2 is a front view showing the configuration of the surface mounting mechanism according to an embodiment of the present invention, Figure 3 of the present invention 4 is a perspective view illustrating a structure of a top mounting mechanism according to an embodiment, and FIG. 4 is a view illustrating a dust removing body and a rack gear of the top mounting mechanism according to an embodiment of the present invention, and FIG. 5 is a top scale according to an embodiment of the present invention. FIG. 6 is a view showing vertical movement of the dust removing body according to the movement of the rack gear of the installation mechanism, and FIG. 6 is a view showing the top and light emitting sheet of the top mounting mechanism according to the embodiment of the present invention, and FIG. The figure which shows the structure of the horizontal adjustment apparatus of the top mounting mechanism which concerns on an example.

Elevation confirmation system through the level measurement according to an embodiment of the present invention includes an elevation measurement device 100, and the elevation information collecting device 900 in communication with the elevation measurement device 100.

Elevation measuring device 100 includes a surface mounting mechanism 200, the surface 300, the distance measuring unit 400, the transmitter 410, the leveler 500 and the elevation information collector 600.

The surface mounting mechanism 200 forms a body portion 210, a horizontal adjustment device 700 at a lower portion of the body portion 210, and a support portion 800 at a lower portion of the horizontal adjustment apparatus 700.

The body portion 210 includes an accommodation space 211 formed therein, a distance measuring device installation hole 212 which is disposed under the accommodation space 211 and communicates with the accommodation space 211 and opens downward, and the accommodation space. It is disposed above the upper portion 211 and communicates with the receiving space 211 and forms a top surface insertion hole 213 opening upward.

The chuck 300 is detachably inserted into the chuck insertion hole 213 of the chuck installation mechanism 200 and the scale is displayed on the circumferential surface.

In the present embodiment, the top surface 300 is a conventional method used for leveling, and a detailed description thereof will be omitted.

The top surface 300 is located between the top support 306 in which the top passage hole 302 is formed to surround the edge of the top 300, and is formed between the top 300 and the top support 306 to form a pipe or mass. The dust removal unit 310 is formed to form the dust removal unit 308 made of a cloth material and the gear connecting unit 309 connected to be connected to the rack gear 320.

The dust removing body 310 is connected to the rack gear 320 in the vertical direction vertically through the gear connector 309.

The rack gear 320 is formed in the receiving space 211 of the body portion 210 and is connected to the top 300 by using the dust removing body 310 on one side of the bottom 300 of the top 300 and the bottom of the top 300 Extend in the direction of the exposure.

The rack gear 320 corresponds to the length of the top 300 and is integrally coupled with the dust remover 310 so that the dust remover 310 also moves up and down along the top and bottom of the rack 300. Is moved in the direction. Accordingly, the dust removing body 310 to wash the foreign matter on the surface of the surface 300.

The rack gear 320 moves in a vertical direction from the bottom of the rear end 300 to the top of the chuck 300.

The pinion gear 330 meshes with the rack gear 320, and when the driving motor 340 is driven, the pinion gear 330 rotates forward and backward to move the rack gear 320 up and down.

The light emitting sheet 350 is installed between the cradle 342 and the top surface 300.

The light emitting sheet 350 has a polyester transparent film 351 having a flexible characteristic, a front electrode layer 352 coated on the entire surface of the polyester transparent film 351 and excellent in light transmittance and conductivity, and a front electrode layer ( A fluorescent layer 353 formed on the rear surface of the 352 to induce electroluminescence, a dielectric layer 354 applied to the rear surface of the fluorescent layer 353 and electrically insulating and reflecting light, and laminated on the rear surface of the dielectric layer 354. The back electrode layer 355, a protective layer 356 formed on the back surface of the back electrode layer 355 to protect from moisture and ultraviolet rays, and an electrode layer 357 formed to be connected to the front electrode layer 352 and the back electrode layer 355. And a connection cable 358 of a predetermined length connected to the electrode layer 357.

The light emitting sheet 350 is provided with a top 300 of a transparent material in order to transmit light to the front surface and a cradle 342 supported on the rear surface.

When the light emitting sheet 350 is supplied with power from the power supply unit 440 through the electrode layer 357 and the connection cable 368, light is emitted through the surface 300 and thus the scale of the surface 300 is in a dark environment. Can be read.

The surface mounting mechanism 200 supplies power to the light emitting sheet 350 by a power supply unit 440 for supplying power, a driving unit 420 for driving the light emitting sheet 350 at predetermined time intervals, and a power supply unit 440. And a control unit 430 for supplying and controlling the light emitting sheet 350 to be driven at a predetermined time interval by the driving unit 420.

The controller 430 may control the driving unit 420 and the power supply unit 440 to sequentially flash over time to control the light emitting sheet 350 to emit light, or may control to emit light continuously.

Through this, the top surface 300 of the transparent material transmits the light emitted from the light emitting sheet 350 so that the scale of the top surface 300 can be read at a long distance or at night.

The surface mounting mechanism 200 forms a horizontal control device 700 to maintain the horizontal level in the lower portion of the body portion 210 according to the inclination.

The horizontal adjusting device 700 includes a body 710 including a first support plate 712 having a flat plate shape and a second support plate 714 spaced a predetermined distance downward from the first support plate 712.

Inside the body 710, a hinge means 720 is installed to enable horizontal adjustment of the first support plate 712.

The hinge means 720 includes an upper hinge portion 722 formed below the first support plate 712, a lower hinge portion 724 formed above the second support plate 714, and an upper hinge portion 722. And a hinge pin 726 for rotatably coupling the lower hinge portion 724.

The hinge means 720 is installed at the center of the body 710 so that the first support plate 712 can rotate at a predetermined angle to the left and right.

The sensing means 730 and the driving means 740 are installed in the body 710 to maintain a horizontal level by adjusting the angle of the first support plate 712.

The sensing means 730 is formed on the lower side of the first support plate 712 and is provided at a predetermined interval on the left and right sides of the balance weight 734 and the balance weight 734 which are rotatably installed left and right according to the inclination of the first support plate 712. The left and right proximity sensors 736 and 738 are spaced apart from each other.

The body 710 is provided with a box 732 for installing the counterweight 734 and the left and right proximity sensors 736 and 738, and the counterweight 734 is rotatable on the upper side of the inside of the box 732. A support plate 739 for supporting is formed.

The left and right proximity sensors 736 and 738 are fixedly spaced apart from each other at regular intervals on the bottom surface of the box 732.

The lower end of the balance weight 734 is located between the left and right proximity sensors 736 and 738.

The counterweight 734 is always perpendicular to the ground plane regardless of the inclination of the first support plate 712.

The sensing means 730 detects the distance that the balance weight 734 approaches the left and right proximity sensors 736 and 738 according to the inclination of the first support plate 712 and transmits a control signal to the driving means 740.

When the body 710 is inclined in the right direction, the counterweight 734 approaches the right proximity sensor 738, and when the body 710 is inclined in the left direction, the counterweight 734 approaches the left proximity sensor 736. do.

The sensing means 730 detects the approach distance between the left and right proximity sensors 736 and 738 and the balance weight 734 to determine the inclination of the first support plate 712 and transmits this information to the driving motor 742.

The driving means 700 is installed on the upper side of the second support plate 714 to maintain the horizontal by adjusting the angle of the first support plate 712 in accordance with the control signal received from the sensing means 730.

The driving means 700 is installed on the driving motor 742 installed on the upper side of the second supporting plate 714 and the lower side of the first supporting plate 712, and is lowered by the driving motor 742 to support the first supporting plate. It consists of a support shaft 746 for adjusting the angle of 712. The support shaft 746 is comprised by a screw shaft.

The drive motor 742 is coupled to the support shaft 746 through the gear box 744 provided on one side. Therefore, when the driving motor 742 is driven in the forward or reverse direction, the support shaft 746 is moved up and down through the gearbox 744 to adjust the angle of the first support plate 712 to maintain horizontality.

The support part 800 is installed below the body part 210 to support the body part 210. In this case, the support part 800 is provided in plural, and stably supports the body part 210.

Each support part 800 has a support part body 810 and a sub support part 820 having a thread formed inward of the support part body 810 to rotate the support part body 810 to vary its length.

Since the length of the support part 800 is variable, the surface mounting mechanism 200 may be located at a place where the surface is not flat.

The range finder 400 is installed in the range finder installation hole 212 of the body portion 210 and measures the distance from the bottom of the surface 300 to the ground. In the present embodiment, the distance meter 400 is a conventional method of measuring distance using ultrasonic waves, infrared rays, and the like, and a detailed description thereof will be omitted.

The transmitter 410 is installed on the side of the body unit 210 to wirelessly transmit the distance value of the range finder 400.

The leveler 500 includes an input device 540 for checking the scale of the top scale 300 installed in the top mounting mechanism 200 and inputting the checked scale, and the scale and distance measurer from the input device 540. The height value from the ground surface to the scale of the scale 300 is calculated by calculating the distance value from 400.

In addition, the leveler 500 may communicate with the reference station 10 and the satellite 20 to obtain an accurate plane position coordinate value.

The reference station 10 includes a GPS antenna 14 and mutually calculates the GPS receiver 14 receiving the position value from the satellite 20 and the current position value and the stored absolute value received from the GPS receiver 14. And a DGPS antenna 15 having a control unit 12 for outputting a GPS correction value, and a DGPS antenna 15, and receiving the GPS correction value from the control unit 12 and transmitting it wirelessly to the outside.

In the present embodiment, the GPS correction value (that is, the position value) calculated through the control unit 12 of the reference station 10 is transferred to the DGPS transmitter 16 and is connected to the DGPS antenna 15 through the DGPS antenna 15. The radio is sent out to the leveler 500.

The leveler 500 includes a DGPS antenna 510, a DGPS receiver 512 that receives GPS correction values from the DGPS transmitter 16 of the reference station 10, and a GPS antenna 520. Using the GPS receiver 522 to receive the current position value from the GPS receiver and the GPS correction value received from the DGPS receiver 512 to determine the precise position of the leveler 500 through the precise position calculation of the GPS antenna 520. The control unit 530 is included.

On the other hand, the general function of the leveler 500 in the present embodiment is a well known art, a detailed description thereof will be omitted.

The elevation information collector 600 includes a storage unit 610 for storing elevation information of each point collected using the leveler 500, and an elevation information transmission module 620 for transmitting elevation information.

The elevation information collecting device 900 is a receiving module 910 for receiving each elevation information obtained at a plurality of points from the elevation information transmitting module 620 of the elevation information collector 600, and the elevation information according to each point. Elevation information DB 920 for storing the, and a display module 930 for displaying the elevation information stored in the elevation information DB (920). At this time, the elevation information collecting device 900 may be carried by the user in the form of a terminal or installed in the leveler 500.

Referring to Figures 1 to 8 look at the state of use of the elevation check system through the level measurement as follows.

First, when the front surface mounting mechanism 200 rotates forward and backward by driving the driving motor 340 under the control of the controller 430, the pinion gear 330 connected to the driving motor 340 is rotated.

As the pinion gear 320 rotates, the rack gear 320 meshed with the pinion gear 320 is driven to move in the vertical direction.

When the rack gear 320 is moved in the vertical direction, the dust remover 310 installed on the top of the rack gear 320 is also moved at the same time so that the scale 300 is removed by the dust remover 308 of the dust remover 310. Wipe off foreign matter on the surface.

When the surface mounting mechanism 200 surveys elevation information at night or in a dark environment, the control unit 430 supplies power to the light emitting sheet 350 by the power supply unit 440 and the light emitting sheet by the driving unit 420. 350 is controlled to be driven at predetermined time intervals.

The surface water rotates the support body 810 of the surface mounting mechanism 200 and the sub support portion 820 is exposed to the outside to extend and adjust the length so that the surface of the surface mounting mechanism 200 is adjusted.

When the body 710 is inclined in the right direction, the counterweight 734 approaches the right proximity sensor 738, and when the body 710 is inclined in the left direction, the counterweight 734 approaches the left proximity sensor 736. do.

The sensing means 730 detects the approach distance between the left and right proximity sensors 736 and 738 and the balance weight 734 to determine the inclination of the first support plate 712 and transmits this information to the driving motor 742.

The driving motor 742 receiving the control signal from the sensing means 730 raises and lowers the support shaft 746 to adjust the angle of the first support plate 712. The counterweight 734 is connected to the right proximity sensor 738. When approaching, the first support plate 712 is inclined in the right direction.

Therefore, the driving motor 742 lowers the support shaft 746 to angle the first support plate 712 to the left to maintain the horizontal level of the first support plate 712.

When the counterweight 734 approaches the left proximity sensor 736, the first support plate 712 is inclined in the left direction.

Therefore, the driving motor 742 raises the support shaft 746 to angle the first support plate 712 in the right direction to maintain the horizontal level of the first support plate 712.

The surface water adjusts the support portion 800 of the surface mounting mechanism 200 to level the surface of the surface mounting mechanism 200.

After that, the machine reads the scale of the surface 300 cleaned by the leveler 500.

At this time, the distance measuring device 400 installed in the surface mounting mechanism 200 measures the distance from the bottom of the surface 300 to the ground, and the measured distance value is transmitted to the leveler 500 through the transmitter 410. .

The leveler 500 obtains elevation information of a point where the scale 300 is installed by summing a scale input by the number of machines and a distance value measured by the distance measurer 400.

After that, the number of meters and the number of machines continuously perform the general leveling method, collect the elevation information of various points, and the elevation information transmission module 620 of the elevation information collector 600 for the elevation information according to the collected location. It is sent to the elevation information collecting device 900 through.

The elevation information collecting device 900 receives the elevation information through the reception module 910 and stores the received elevation information in the elevation information DB 920 according to the corresponding position.

According to the present invention, the surface of the surface 300 can be easily and quickly wiped because the surface of the surface 300 can be wiped conveniently and quickly when the surface of the surface 300 is removed. When the number of machines can be more precise surveying, it is possible to integrate the elevation information from the elevation measuring device 100 in progress in various places, it is possible to integrate the management of the elevation information.

The embodiments of the present invention described above are not implemented only by the apparatus and / or method, but may be implemented through a program for realizing functions corresponding to the configuration of the embodiment of the present invention, a recording medium on which the program is recorded And such an embodiment can be easily implemented by those skilled in the art from the description of the embodiments described above.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

100: elevation measuring device 200: surface mounting mechanism
210: body portion 211: accommodation space
212: distance measuring instrument installation hole 213: surface insertion hole
300: Surface 306: Surface Support
308: dust removal unit 310: gear coupling
310: dust removing body 310: dust
320: rack gear 330: pinion gear
340: drive motor 342: holder
350: light emitting sheet 351: transparent film
352: front electrode layer 353: fluorescent layer
354: dielectric layer 355: back electrode layer
356: protective layer 357: electrode layer
358: connection cable 400: range finder
410: transmitter 420: drive unit
430: control unit 440: power unit
500: leveler 510: DGPS antenna
512: DGPS receiver 520: GPS antenna
522: GPS receiver 530: control unit
540: input device 600: elevation information collector
610: storage unit 620: elevation information transmission module
700: leveling device 710: body
712: first support plate 714: second support plate
720: hinge means 722: upper hinge portion
724: lower hinge portion 726: hinge pin
730: sensing means 732: box
734: counterweight 736: left proximity sensor
738: proximity sensor 739: support plate
740: driving means 742: driving motor
744: gearbox 746: support shaft
800: support portion 810: support portion main body
820: sub support portion 900: surface information collecting device
910: receiving module 920: elevation information DB
930: display module

Claims (1)

An accommodation space 211 formed therein, a distance measuring device installation hole 212 disposed in a lower portion of the accommodation space 211 and communicating with the accommodation space 211 and opening downward, and the accommodation space 211 It is disposed in the upper portion to form a top surface insertion hole 213 in communication with the receiving space 211 is opened upwards, is detachably inserted into the top surface insertion hole 213 is built in a predetermined length in the vertical direction and the peripheral surface The scale 300 is displayed on the scale 300 and the distance measuring device 400 is installed in the distance measuring device mounting hole 212 of the surface mounting mechanism 200 and measures the distance from the bottom surface of the surface 300 to the ground and Is installed on the surface mounting mechanism 200, the body portion 210 including a transmitter 410 for transmitting the distance value of the distance measuring unit 400, and the horizontal adjustment device 700 in the lower portion of the body portion 210 ) To form a support portion 800 in the lower portion of the horizontal adjustment device 700 Installation chuck mechanism (200);
It is provided with an input device 540 for checking the scale of the scale 300 installed in the top mounting mechanism 200 and inputting the value of the checked scale, the scale value and the distance measurer from the input device 540 A leveler 500 for calculating the height from the ground to the scale of the scale 300 by calculating the distance value from 400;
The storage unit 610 is connected to the leveler 500 and inputs and stores the elevation information of each point collected by the leveler 500, and the elevation information for transmitting the elevation information stored in the storage unit 610. An elevation information collector 600 comprising an elevation information collector 600 having a transmission module 620; And
A receiving module 910 connected to the elevation information collector 600 and receiving respective elevation information obtained at a plurality of points from the elevation information transmitting module 620 of the elevation information collector 600, and the receiving module 910 Elevation information collecting device 900 comprising an elevation information DB (920) for storing the elevation information according to each point received by the) and a display module 930 for displaying the elevation information stored in the elevation information DB (920) Include,
The top surface 300 is made of a dust material made of cloth material formed between the top surface support hole 302 and the top surface 300 and the top surface support 306 formed in a lump shape to surround the rim. And a dust removing body 310 formed of a gear connector 309 connected to the rack gear 320 to form a reject 308, wherein the rack gear 320 has an accommodation space of the body portion 210. It is formed in the 211 and connected to the surface 300 using the dust removal body 310 on the lower side of the surface 300, the rack gear 320 is the pinion gear in the receiving space (211) ( 330 is moved up and down in accordance with the rotation of the pinion gear 330, and corresponds to the length of the top 300, and integrally coupled with the dust removing body 310 to the vertical movement of the rack gear 320 The dust removing body 310 is also moved along the vertical direction of the surface 300 to the surface of the surface 300 And cleaning the foreign matter,
A light emitting sheet 350 is installed on the rear surface of the top surface 300 to emit light, and the horizontal adjusting device 700 moves downward from the first support plate 712 and the first support plate 712 in the form of a plate. An upper hinge portion 722 is formed on the lower side of the first support plate 712, and the second support plate including a body 710 consisting of a second support plate 714 spaced apart from a certain distance; A lower hinge portion 724 formed on the upper side of the 714, and a hinge pin 726 for rotatably coupling the upper hinge portion 722 and the lower hinge portion 724, the first support plate 712 Hinge means 720 to enable horizontal adjustment of the balance weight 734 formed on the lower side of the first support plate 712 and installed to be rotated left and right according to the inclination of the first support plate 712, The left and right proximity sensors 736 and 738 are spaced apart at regular intervals on the left and right sides of the counterweight 734, respectively. Detection means 730 for detecting the inclination of the first support plate 712 and the first support plate according to a control signal received from the detection means 730 and installed on an upper side of the second support plate 714. Elevation checking system through a level measurement comprising a drive means (740) to adjust the angle of the (712) to maintain horizontal.

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